Devices and methods related to interconnect conductors to reduce de-lamination

ABSTRACT

Disclosed are systems, devices and methods for utilizing an interconnect conductor to inhibit or reduce the likelihood of de-lamination of a passivation layer of an integrated circuit die. In some implementations, a metal layer in ohmic contact with an intrinsic region of a semiconductor substrate can be partially covered by a passivation layer such as a dielectric layer. An interconnect conductor electrically connected to the metal layer can include an extension that covers an edge of the passivation layer to thereby inhibit the edge from lifting up. In some implementations, the metal layer in combination with a contact pad also in ohmic contact with the intrinsic region can yield a conduction path through the intrinsic region during an electrostatic discharge (ESD) event. In such a configuration, the interconnect conductor can route the ESD charge to a ground.

RELATED APPLICATIONS

This application is a non-provisional of and claims priority to U.S.Provisional Application No. 61/588,999, filed on Jan. 20, 2012, entitled“DEVICES AND METHODOLOGIES RELATED TO ELECTROSTATIC DISCHARGE PROTECTIONBENIGN TO RF OPERATION,” which is hereby incorporated herein byreference in its entirety.

BACKGROUND

1. Field

The present disclosure generally relates to the field of semiconductortechnology, and more particularly, to electrostatic discharge protectionfor semiconductor devices.

2. Description of the Related Art

Electrostatic discharge (ESD) is a sudden and usually undesirable flowof charge between two objects at different electrical potentials. ESDcan be harmful to solid state electronics such as integrated circuits.

Some portions of an integrated circuit (IC) can be equipped with ESDprotection devices such as diodes. However, such devices typicallyaffect radiofrequency (RF) properties of the IC.

SUMMARY

In a number of implementations, the present disclosure relates to adevice that includes a semiconductor substrate having an intrinsicregion. The device further includes a circuit disposed on thesemiconductor substrate. The device further includes a first conductordisposed relative to the intrinsic region and electrically connected tothe circuit. The device further includes a second conductor disposedrelative to the intrinsic region and the first conductor. The secondconductor is configured so that a potential difference greater than aselected value between the first and second conductors results in aconduction path through the intrinsic region between the first andsecond conductors.

In some embodiments, the device can be a semiconductor die. Thesubstrate can further include an insulating region disposed between thefirst and second conductors and above the intrinsic region so that theconduction path through the intrinsic region is away from a surface ofthe substrate.

In some embodiments, the device can further include a ground that iselectrically connected to the second conductor. In some embodiments,each of the first and second conductors can be formed from metal suchthat the conduction path includes a metal-semiconductor-metal junction.The metal-semiconductor-metal junction can include a first turn-onvoltage for conduction along a first direction between the first andsecond conductors. The metal-semiconductor-metal junction can furtherinclude a second turn-on voltage for conduction along a second directionbetween the first and second conductors. The first and second turn-onvoltages can have different magnitudes. The magnitude of the firstturn-on voltage can be lower than the magnitude of the second turn-onvoltage. The conduction along the first direction can include conductionfrom the first conductor to the second conductor through the intrinsicregion. The first turn-on voltage can be selected to facilitate theconduction along the first direction when the circuit is subjected to anelectrostatic discharge (ESD) but not significantly interfere withoperation of the circuit when not subjected to the EDS.

In some embodiments, each of the first and second conductors can form anohmic contact with the intrinsic region. The intrinsic region caninclude a bulk intrinsic region that allows injection of charge throughat least one of the first and second conductors. The first and secondconductors can be configured to favor the injection of charge into thebulk intrinsic region through the first conductor during anelectrostatic discharge (ESD). The second conductor can be geometricallyconfigured to facilitate the favored injection of charge through thefirst conductor.

The bulk intrinsic region and the second conductor's geometricconfiguration can be configured such that capacitance resulting from thesecond conductor has a substantially negligible effect on operation ofthe circuit when not subjected to the EDS. The operation of the circuitcan include a radio-frequency (RF) operation when not subjected to theEDS.

In some embodiments, the semiconductor substrate can include first andsecond sides that face substantially opposite directions. Both of thefirst and second conductors can be positioned on the first side of thesemiconductor substrate. At least one of the first and second conductorscan be formed directly on a surface of the first side of thesemiconductor substrate. At least one of the first and second conductorscan be formed within a recessed feature defined on the first side of thesemiconductor substrate. The first conductor can be part of an epitaxialstructure formed on the first side of the semiconductor substrate.

In some embodiments, the first conductor can be positioned on the firstside of the semiconductor substrate and the second conductor can bepositioned on the second side of the semiconductor substrate. At leastone of the first and second conductors can be formed within a recessedfeature defined on the side associated with the conductor. The recessedfeature can be dimensioned to provide a desirable dimension of theintrinsic region between the first and second conductors.

In some embodiments, the circuit can include a radio-frequency (RF)circuit. The first conductor can include a contact pad configured toreceive an input RF signal for the RF circuit. The second conductor canbe configured as a strip that extends at least partially around thecontact pad's perimeter. The contact pad can have a substantiallyrectangular shape, and the strip can include a substantially right-anglecorner positioned at a selected distance from one of the corners of therectangular-shaped contact pad.

In some embodiments, the RF circuit can include a low-noise amplifier(LNA) and/or a passive device configured to facilitate operation of theRF circuit. The passive device can include, for example, a capacitorsuch as a DC-blocking capacitor and/or a resistor.

In some embodiments, the semiconductor substrate can include galliumarsenide (GaAs). Other types of semiconductor substrate can also benefitfrom one or more features of the present disclosure.

According to some implementations, the present disclosure relates to amethod for fabricating a semiconductor device. The method includesproviding a semiconductor substrate having an intrinsic region. Themethod further includes forming a first conductor at a first locationrelative to the intrinsic region. The method further includes forming asecond conductor at a second location relative to the intrinsic regionto form a discharge path through the intrinsic region between the firstand second conductors. The discharge path is capable of passing currentwhen a potential difference between the first and second conductorsexceeds a selected value.

In some embodiments, the forming of the first conductor and the formingof the second conductor each can include forming an ohmic contactbetween the respective conductor and the intrinsic region. In someembodiments, the method can further include forming an insulating regionbetween the first and second conductors such that the discharge paththrough the intrinsic region is below the insulating region.

In some implementations, the present disclosure relates to asemiconductor die that includes a substrate configured to receive aplurality of components, with the substrate having an intrinsic region.The die further includes a first conductor disposed relative to theintrinsic region. The die further includes a second conductor disposedrelative to the intrinsic region and the first conductor. The secondconductor is configured so that a potential difference greater than aselected value between the first and second conductors results in aconduction path through the intrinsic region between the first andsecond conductors.

In accordance with some implementations, the present disclosure relatesto a radio-frequency (RF) module that includes a packaging substrateconfigured to receive a plurality of components. The module furtherincludes a die mounted on the packaging substrate. The die includes aradio-frequency (RF) circuit and an intrinsic region. The die furtherincludes a first conductor and a second conductor disposed relative tothe intrinsic region. The first and second conductors are configured sothat a potential difference greater than a selected value between thefirst and second conductors results in a conduction path through theintrinsic region between the first and second conductors.

In some embodiments, the module can further include a ground planeelectrically connected to the second conductor.

In a number of teachings, the present disclosure relates to a wirelessdevice that includes an antenna, and a receiver circuit coupled to theantenna and configured to process a radio-frequency (RF) signal. Thewireless device further includes a monolithic microwave integratedcircuit (MMIC) configured to facilitate the processing of the RF signal.The MMIC includes a semiconductor substrate with an intrinsic region andan RF circuit disposed on the semiconductor substrate. The MMIC furtherincludes a first conductor disposed relative to the intrinsic region andelectrically connected to the RF circuit. The MMIC further includes asecond conductor disposed relative to the intrinsic region. The firstand second conductors are configured so that a potential differencegreater than a selected value between the first and second conductorsresults in a conduction path through the intrinsic region between thefirst and second conductors.

In some embodiments, the RF circuit can include a low noise amplifier(LNA). In some embodiments, the wireless device can further include atransmitter circuit coupled to the antenna and configured to generate atransmit RF signal.

In a number of implementations, the present disclosure relates to astructure for electrostatic discharge (ESD) protection. The structureincludes an ohmic metal disposed on an intrinsic semiconductor substrateand positioned adjacent to a location on the intrinsic semiconductorsubstrate susceptible to an ESD. The structure is configured to besubstantially benign electrically to radiofrequency (RF) signals passingthrough the location.

In some implementations, the present disclosure relates to a device thatincludes a die having a semiconductor substrate with an intrinsicregion. The device further includes a metal layer in ohmic contact withthe intrinsic region. The device further includes a passivation layerformed over the metal layer and the intrinsic region. The passivationlayer defines an opening dimensioned to expose at least a portion of themetal layer. The device further includes an interconnect conductordisposed over the metal layer and electrically connected to the metallayer through the opening. The interconnect conductor includes anextension that extends over an edge of the opening of the passivationlayer to inhibit or reduce the likelihood of the passivation layerde-laminating from the edge.

In some embodiments, the passivation layer can include a dielectriclayer. In some embodiments, the interconnect conductor can be connectedto a ground.

In some embodiments, the device can further include a radio-frequency(RF) circuit implemented on the die. In some embodiments, the device canfurther include a contact pad connected to the RF circuit and in ohmiccontact with the intrinsic region. The contact pad and the metal layercan be configured so that a potential difference greater than a selectedvalue between the contact pad and the metal layer results in aconduction path through the intrinsic region between the contact pad andthe metal layer. The conduction path can include ametal-semiconductor-metal junction. The metal-semiconductor-metaljunction of the conduction path can be configured to provide a dischargepath during an electrostatic discharge (ESD) event.

In some embodiments, the contact pad can be configured to receive aninput RF signal for the RF circuit. The RF circuit can include alow-noise amplifier (LNA).

In some embodiments, the interconnect conductor can be configured as astrip that extends near a perimeter of the die. In some embodiments, thesemiconductor substrate can include gallium arsenide (GaAs). Other typesof semiconductor substrate can also benefit from one or more features ofthe present disclosure.

According to a number of implementations, the present disclosure relatesto a method for fabricating a semiconductor device. The method includesproviding a semiconductor substrate having an intrinsic region. Themethod further includes forming metal layer in ohmic contact with theintrinsic region. The method further includes forming a passivationlayer over the metal layer and the intrinsic region such that thepassivation layer defines an opening dimensioned to expose at least aportion of the metal layer. The method further includes forming aninterconnect conductor over the metal layer such that the interconnectconductor is electrically connected to the metal layer. The interconnectconductor includes an extension that extends over an edge of the openingof the passivation layer to inhibit or reduce the likelihood of thepassivation layer de-laminating from the edge.

In some embodiments, the method can further include forming aradio-frequency circuit on the semiconductor substrate. In someembodiments, the method can further include forming and connecting acontact pad to the RF circuit. The contact pad can be in ohmic contactwith the intrinsic region. The contact pad and the metal layer can beconfigured so that a potential difference greater than a selected valuebetween the contact pad and the metal layer results in a conduction paththrough the intrinsic region between the contact pad and the metallayer. In some embodiments, the passivation layer can include adielectric layer.

According to some implementations, the present disclosure relates to aradio-frequency (RF) module that includes a packaging substrateconfigured to receive a plurality of components. The module furtherincludes a semiconductor die mounted on the packaging substrate. The dieincludes an intrinsic region. The die further includes a metal layer inohmic contact with the intrinsic region. The die further includes apassivation layer formed over the metal layer and the intrinsic region.The passivation layer defines an opening dimensioned to expose at leasta portion of the metal layer. The die further includes an interconnectconductor disposed over the metal layer and electrically connected tothe metal layer through the opening. The interconnect conductor includesan extension that extends over an edge of the opening of the passivationlayer to inhibit or reduce the likelihood of the passivation layerde-laminating from the edge.

In some embodiments, the module can further include a ground planeelectrically connected to the interconnect conductor. In someembodiments, the module can further include a radio-frequency (RF)circuit implemented on the die.

In some embodiments, the module can further include a contact padconnected to the RF circuit and in ohmic contact with the intrinsicregion. The contact pad and the metal layer can be configured so that apotential difference greater than a selected value between the contactpad and the metal layer results in a conduction path through theintrinsic region between the contact pad and the metal layer.

In a number of implementations, the present disclosure relates to awireless device that includes an antenna, and a receiver circuit coupledto the antenna and configured to process a radio-frequency (RF) signal.The wireless device further includes a monolithic microwave integratedcircuit (MMIC) configured to facilitate the processing of the RF signal.The MMIC includes a semiconductor substrate with an intrinsic region andan RF circuit disposed on the semiconductor substrate. The MMIC furtherincludes a metal layer in ohmic contact with the intrinsic region. TheMMIC further includes a passivation layer formed over the metal layerand the intrinsic region. The passivation layer defines an openingdimensioned to expose at least a portion of the metal layer. The MMICfurther includes an interconnect conductor disposed over the metal layerand electrically connected to the metal layer through the opening. Theinterconnect conductor includes an extension that extends over an edgeof the opening of the passivation layer to inhibit or reduce thelikelihood of the passivation layer de-laminating from the edge.

In some embodiments, the RF circuit can include a low noise amplifier(LNA).

For purposes of summarizing the disclosure, certain aspects, advantagesand novel features of the inventions have been described herein. It isto be understood that not necessarily all such advantages may beachieved in accordance with any particular embodiment of the invention.Thus, the invention may be embodied or carried out in a manner thatachieves or optimizes one advantage or group of advantages as taughtherein without necessarily achieving other advantages as may be taughtor suggested herein.

The present disclosure relates to U.S. patent application Ser. No.______ [Attorney Docket SKYWRKS.137A1], titled “DEVICES AND METHODSRELATED TO ELECTROSTATIC DISCHARGE PROTECTION BENIGN TO RADIO-FREQUENCYOPERATION,” filed on even date herewith and hereby incorporated byreference herein in its entirety.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A-1E show examples of an electrostatic discharge (ESD) structurethat includes first and second conductors with an intrinsicsemiconductor region therebetween.

FIG. 2 shows that in some implementations, one or more conductors of theESD structure can be formed as part of an epitaxial layer.

FIG. 3A shows that in some implementations, the discharge structure ofFIGS. 1 and 2 can be characterized as a diode configured to provide anESD path under certain conditions.

FIG. 3B shows that in some embodiments, the diode of FIG. 3A can becharacterized as having functionality similar to, for example, a p-i-ndiode.

FIG. 4 shows an example I-V curve having different forward and reverseturn-on voltages of an example ESD structure.

FIG. 5 shows an example integrated circuit device having one or more ESDstructures configured to provide ESD protection.

FIG. 6 shows an enlarged view of the device of FIG. 5, where an ESDstructure can include a first conductor such as a bond pad and a secondconductor separated from the first conductor by an intrinsicsemiconductor region.

FIG. 7A shows a closer view, including a sectional view, of the exampleESD structure of FIG. 6.

FIG. 7B shows a closer sectional view of the first conductor of the ESDstructure of FIG. 7A.

FIG. 7C shows a closer sectional view of the second conductor of the ESDstructure of FIG. 7A.

FIG. 8 shows a photograph of a section of an example ESD, where anelectrical current flow is shown to occur between the first and secondconductors.

FIGS. 9A and 9B show that in some embodiments, an ESD structure havingone or more features as described herein can be particularly useful whenimplemented at or near an RF input location.

FIGS. 10A and 10B show that in some embodiments, an ESD structure havingone or more features as described herein can be substantially benignwith respect to various RF functionalities of an RF device whileproviding ESD protection.

FIG. 11 shows that in some implementations, an ESD structure can beconfigured in a number of different ways to provide differentadvantageous features.

FIG. 12 shows a process that can be implemented to fabricate an ESDstructure having one or more features as described herein.

FIG. 13 shows a process for fabricating an ESD structure where first andsecond conductors can form ohmic contacts with an intrinsicsemiconductor.

FIG. 14 shows that in some implementations, an interconnect conductorthat interconnects one or more ESD structures can be configured toreduce likelihood of de-lamination of a dielectric layer.

FIGS. 15A-15C show sectional views of examples of the interconnectconductor of FIG. 14 formed over an ESD structure.

FIG. 16 shows a sectional view of an example of the interconnectconductor of FIG. 14 formed over a dielectric layer.

FIG. 17 shows a process that can be implemented to fabricate ade-lamination-resistant structure as described herein.

FIG. 18 shows that in some embodiments, one or more features of thepresent disclosure can be implemented on a semiconductor die.

FIG. 19 shows that in some embodiments, one or more features of thepresent disclosure can be implemented in a packaged RF module.

FIG. 20 shows that in some embodiments, one or more features of thepresent disclosure can be implemented in a wireless device.

DETAILED DESCRIPTION OF SOME EMBODIMENTS

The headings provided herein, if any, are for convenience only and donot necessarily affect the scope or meaning of the claimed invention.

Described herein are various examples of devices and methods related toan electrostatic discharge (ESD) structure. ESD is generally understoodto be a relatively sudden and momentary flow of electrical currentbetween two locations at different electrical potentials.

In the context of electronics, such unwanted current can damage devicessuch as integrated circuits (ICs). Such ICs are often formed fromsemiconductor materials such as silicon and gallium arsenide (GaAs), andsuch semiconductor materials themselves can suffer damage when subjectedto sufficiently high voltages.

To reduce occurrence of ESDs and/or to mitigate damages resulting fromESDs, antistatic devices and/or ESD protection devices can be providedor formed on IC devices. In some situations, such devices can affect howan IC device operates. For example, an IC that is configured forradio-frequency (RF) operation can be affected by an ESD protectiondevice in an adverse manner.

As described herein, an ESD structure can be formed on a semiconductorsubstrate so as to provide a desirable ESD protection functionalitywhile not significantly impacting other properties such as RF-relatedproperties. In some implementations, such a structure can include asemiconductor substrate. First and second conductors can be disposed onthe substrate such that an intrinsic semiconductor region is between thetwo conductors.

Under some conditions, such an arrangement can result in a conductionpath being formed through the intrinsic region between the twoconductors. Such conditions can include a situation where an electricalpotential difference between the first and second conductors exceeds aselected value. As described herein, such a value can be selected so asto allow conduction through the intrinsic region under, for example, anESD condition. Under normal operating conditions, the intrinsic regioncan substantially insulate the two conductors from each other. Further,and as described herein, an ESD structure can be configured so as toyield relatively low capacitance that has reduced or substantiallyinsignificant effect on normal operation (such as RF operation) of anIC.

In some embodiments, the first conductor can be part of an IC and/or bea part configured to facilitate electrical connection for the IC. Thesecond conductor can be electrically connected to a ground or any othersuitably configured charge sink. Thus, when an ESD event occurs at thefirst conductor, the pathway created by the ESD condition allows theexcess charge to be routed to the second conductor through the intrinsicregion and away from the IC. Examples of such first and secondconductors and various configurations are described herein in greaterdetail.

FIGS. 1A-1E show non-limiting examples of how the first and secondconductors can be arranged on a semiconductor substrate. In an exampleconfiguration 100 of FIG. 1A, a first conductor 104 and a secondconductor 106 can be disposed on a first surface 108 (such as a topsurface) of a semiconductor substrate 102. In some embodiments, each ofthe first and second conductors 104, 106 can include metal that forms anohmic contact (112, 114) with the semiconductor substrate 102.

In some implementations, the semiconductor substrate 102 can include anintrinsic region such that at least a portion of each of the ohmiccontacts formed by the first and second conductors 104, 106 is with theintrinsic region. In some embodiments, substantially all of the firstand second conductors' ohmic contacts can be on different portions ofthe intrinsic region of the substrate 102. In some embodiments, and asdescribed herein, an intrinsic region can be configured so as to providean electrical pathway between the first and second conductors 104, 106under some conditions.

As shown in FIG. 1A, the configuration 100 having the foregoingproperties can yield an electrical conduction pathway 116 between thefirst and second conductors 104, 106 through the intrinsic region of thesubstrate 102. As described herein, such a conduction pathway can remainoff (e.g., substantially insulating) under normal operating conditions,and advantageously be turned on for conduction under selected conditionssuch as during an ESD event. The example conduction pathway 116 isdepicted as being capable of conducting electricity both ways betweenthe first and second conductors 104, 106. In some embodiments asdescribed herein, electrical current flow in one direction can befavored over the other direction so as to yield a desirable ESDprotection functionality where the current flows away from an area beingprotected.

In an example configuration 120 of FIG. 1B, a first conductor 104 can bedisposed on a first surface 108 (such as a top surface) of asemiconductor substrate 102 in a manner similar to that of FIG. 1A. Inthis example, a second conductor 124 can be disposed on a second surface122 (such as a side surface adjacent the top surface) of the samesubstrate 102. In the example of FIG. 1B, the top surface 108 can be amain surface where various IC components are formed, and the sidesurface 122 can be, for example, a side wall surface of an edge. In someembodiments, one or both of the conductors 104, 124 can be configured toform ohmic contact(s) with the substrate 102 in a manner similar to theexample of FIG. 1A. In some implementations, the semiconductor substrate102 can include an intrinsic region so as to yield properties and/orfunctionalities similar to the example configuration 100 of FIG. 1A,including the advantageous turning on of an electrical conductionpathway 126 under selected conditions such as an ESD event.

In an example configuration 130 of FIG. 1C, a first conductor 104 can bedisposed on a first surface 108 (such as a top surface) of asemiconductor substrate 102 in a manner similar to that of FIG. 1A. Inthis example, a second conductor 134 can be disposed on a feature suchas a via 132 formed on the first surface 108. In some embodiments, oneor both of the conductors 104, 134 can be configured to form ohmiccontact(s) with the substrate 102 in a manner similar to the example ofFIG. 1A. In some implementations, the semiconductor substrate 102 caninclude an intrinsic region so as to yield properties and/orfunctionalities similar to the example configuration 100 of FIG. 1A,including the advantageous turning on of an electrical conductionpathway 136 under selected conditions such as an ESD event.

FIG. 1D depicts another example configuration 140 where a firstconductor 104 can be disposed on a first surface 108 (such as a topsurface) of a semiconductor substrate 102 in a manner similar to that ofFIG. 1A. A second conductor 144 is depicted as being disposed on theopposite surface 142 (such as a bottom surface) of the semiconductorsubstrate 102. In some implementations, the top surface 108 of thesubstrate 102 can include various IC components. In some embodiments,one or both of the conductors 104, 144 can be configured to form ohmiccontact(s) with the substrate 102 in a manner similar to the example ofFIG. 1A. In some implementations, the semiconductor substrate 102 caninclude an intrinsic region so as to yield properties and/orfunctionalities similar to the example configuration 100 of FIG. 1A,including the advantageous turning on of an electrical conductionpathway 146 under selected conditions such as an ESD event.

As described herein, the turning on of an electrical conduction pathwaythrough an intrinsic semiconductor region can be triggered by anelectrical potential difference between first and second conductorsexceeding a selected value. Such a selected value can depend on factorsthat include, but not limited to, distance between the conductors,composition of the intrinsic semiconductor, and dimensions of theconductors. Accordingly, a design of an ESD protection structure can bebased on one or more of these factors.

For example, suppose that the substrate 102 of FIG. 1D forms a diehaving a given thickness. Such a thickness may be result in a turn-onpotential that is too high. To lower the turn-on potential, the twoconductors can be positioned closer to each other as depicted in FIG.1E, where an example configuration 150 includes a second conductor 154that is positioned closer to a first conductor 104 (on a first surface108 such as a top surface) by being disposed in a recess 152 (such as avia or a depression) defined by a second surface 142 (such as a bottomsurface). Accordingly, a conduction path 156 through an intrinsic regionof a semiconductor substrate 102 can be turned on at a suitablepotential difference. In some embodiments, such a suitable potentialdifference can be lower than that of a configuration where the secondconductor is formed on the second surface (assuming similar thicknessand composition of the substrates) and thus separated further from thefirst conductor.

In another example, and as described herein in greater detail, shapesand sizes of the first and second conductors can be selected to providefunctionalities such as, but not limited to, a desired turn-on profilewhile having a reduced or substantially nil contribution in one or moreradio-frequency (RF) affecting parameters (e.g., capacitance). In someembodiments, and as further described herein, such a desired turn-onprofile can be configured so as to favor one conduction path directionover the other.

In the examples described in reference to FIGS. 1A-1E, variousconductors are depicted as being formed directly on their respectivesurfaces of semiconductor substrates. It will be understood, however,that such a feature is not a requirement.

For example, as shown in a configuration 180 of FIG. 2, a firstconductor for facilitating a selected turned-on conduction through anintrinsic semiconductor region of a substrate 102 can be disposed on astructure 182 (such as epitaxial layers) that is formed on a firstsurface 108 (such as a top surface) of the substrate 102. In the exampleshown, a second conductor 184 is also disposed on the top surface 108 ofthe substrate 102. In some embodiments, the conductors 102, 184 can beconfigured to form ohmic contacts with their respective surfaces. Insome implementations, the epi-layers structure 182 and the semiconductorsubstrate 102 can include intrinsic regions so as to yield propertiesand/or functionalities similar to the example configurations of FIGS.1A-1E, including the advantageous turning on of an electrical conductionpathway 186 under selected conditions such as an ESD event.

In some implementations, the various example structures described inreference to FIGS. 1 and 2 can include a feature where an electricalconduction pathway is established when the potential difference betweenthe two conductors exceeds some threshold value. Further, such aconduction pathway can be directional such that current flow is allowedone way (e.g., from the first conductor to the second conductor) butinhibited or reduced in the opposite direction.

While it is not desired or intended to be bound by any particular theoryor model, a device having one or more features described herein can becharacterized as a diode 200 as depicted in FIG. 3A. Such a diode can beconfigured so as to allow current flow only in one direction (e.g.,arrow 206) when its two terminals 202, 204 are biased appropriately(e.g., forward bias greater than a threshold value).

In the context of a conduction pathway being through an intrinsicsemiconductor material, the diode 200 of FIG. 3A can be represented asan x-i-y type diode 210 depicted in FIG. 3B, where each of x and y canbe n-type or p-type. In some embodiments, x and y can be the same typeof material. For example, if ohmic contacts formed by the first andsecond conductor include n-type interfaces between the conductors'metals and the intrinsic semiconductor, then the diode 210 can be ann-i-n diode. Similarly, a p-i-p diode can also be implemented.

Again, while it is not desired or intended to be bound by any particulartheory or model, the example diode's first terminal 212 can correspondto the first conductor (e.g., 104 and 184 in FIGS. 1 and 2), and thesecond terminal 214 to the second conductor (e.g., 106, 124, 134, 144,154, and 184). Accordingly, the first conductor can form an ohmiccontact with the intrinsic region so as to include an x-type-intrinsiclike junction (with x being p-type or n-type). Similarly, the secondconductor can form an ohmic contact with the intrinsic region so as toinclude a y-type-intrinsic like junction (with y being p-type orn-type).

FIG. 4 shows an I-V curve 220 associated an example structure similar tothat of FIG. 1A. A forward current (e.g., from the first conductor 104to the second conductor 106) is depicted as beginning to turn on at aforward bias voltage of V_(f). In the example shown, V_(f) has a valueof about 5 volts, and the current's magnitude increases rapidly afterabout 10 volts. It will be understood that V_(f) can be selected to belower or higher.

In the example I-V curve 220, a reverse current is shown to turn on at areverse bias voltage V_(r). In the example shown, V_(r) has a value ofabout −5 volts, and the current's magnitude increases at a slower ratethan that of the forward current. It will be understood that V_(r) canbe selected to be lower or higher.

In some implementations, and as shown in FIG. 4, an asymmetry in the I-Vcurve, in the context of magnitudes of V_(f) and V_(r) and/orcurrent-increase profiles, can be due to differences in the first andsecond conductors. For example, differences in ohmic contact areas ofthe two conductors can yield such an asymmetry. Accordingly, firstand/or second conductors can be configured so as to yield a desired I-Vprofile that provides, for example, a funnel-like functionality wherecharge can fill the intrinsic region easier through one conductor (e.g.,first conductor) than the other conductor (e.g., second conductor). Sucha functionality can provide ESD protection by diverting the charge awayfrom the first conductor to the second conductor, while making thereverse flow of charge (from the second conductor to the firstconductor) less likely.

In some implementations, the foregoing example of configuring one ormore of the conductors about an intrinsic semiconductor region toachieve a desired charge flow can be part of a systematic approach toESD protection. Such an approach can be designed and implemented so asto allow a discharge structure to work in conjunction with one or moreexisting structures to allow build up and discharge of charge in adesirable manner. For example, an existing bond pad can act as a firstconductor, and a discharge conductor acting as a second conductor can bedimensioned and positioned relative to the bond pad so as to achieve adesired discharge property.

In another example, a discharge conductor can be dimensioned andpositioned relative to a passive device where charge buildup is likely.For example, a discharge conductor can be positioned relative to acapacitor or a resistor so as to allow discharge of charge from such adevice to the discharge conductor.

In some implementations, an existing structure or device can beconfigured to further increase the robustness of ESD protection, and/orto provide greater control in how such ESD protection can beeffectuated. For example, suppose that a MIM (metal-insulator-metal)capacitor is provided in a circuit design, and that it is not desirableto have an ESD occur at or close to a selected conductor (e.g., anadjacent ohmic metal such as a contact to a resistor or a source/drainmetal). If such a selected conductor is formed with ohmic contact withan intrinsic semiconductor substrate shared with a bottom metal (also inohmic contact with the intrinsic semiconductor substrate) of the MIMcapacitor, an unintentional ESD pathway can be provided between thecapacitor and the selected conductor as described herein. To inhibitsuch a discharge path, a MIM capacitor can be configured so that itsbottom metal layer is positioned on, for example, a nitride layerinstead of directly on the intrinsic semiconductor. Such a nitride layercan inhibit or reduce the likelihood of discharge from the metal of thecapacitor into the semiconductor through body or surface charge states.

In some implementations, a discharge conductor can be positionedrelative to an intrinsic semiconductor region so as to yield a desiredESD protection functionality. For example, effectiveness of a dischargeconductor in receiving charge can be increased by a selectivelyorienting the discharge conductor with an average crystal orientation ofthe semiconductor substrate (e.g., GaAs). In the context of astrip-shaped discharge conductor, generally aligning the strip extensiondirection with a selected crystal orientation can improve theeffectiveness of charge transfer between the strip conductor and thesemiconductor substrate (e.g., the strip conductor receiving charge fromthe semiconductor substrate). Such a configuration can be based on aproperty of electrical conduction varying with crystal orientation. Insome implementations, transistors are sometimes oriented to takeadvantage of such a property. Similarly, a discharge structure can alsobe oriented to take advantage of such a property.

FIG. 5 shows an example of a device 230 having a number of ESDstructures disposed about their respective conductor structures. FIG. 6shows an enlarged view of one of the example ESD structures and itscorresponding conductor structure. It will be understood that a givendevice can have more or less ESD structures than the four example ESDstructures described in reference to FIG. 5.

The example device 230 in FIG. 5 is a monolithic microwave integratedcircuit (MMIC). In the example MMIC 230, bond pads (244 a, 244 b, 244 c,244 d) formed on a substrate having an intrinsic region 232 can beconsidered to be first conductor structures, and their correspondingL-shaped second conductors (246 a, 246 b, 246 c, 246 d) yield ESDstructures 240 a, 240 b, 240 c, 240 d. As shown in the example MMIC 230,the L-shaped second conductors 246 can be electrically connected to aground plane (not shown) through an interconnect metal trace 250 and athrough-wafer via 252. In the plan views of FIGS. 5 and 6, at least aportion of the substrate region between the first and second conductorscan include an insulating region on the surface, and the intrinsicregion 232 can be located below such an insulating region. Thus, theintrinsic region 232 in ohmic contact with the first and secondconductors provides an electrical pathway that can be turned on throughthe bulk of the intrinsic region and away from the surface.

FIG. 6 shows an enlarged view of the example ESD structure 240 c of FIG.5. As shown, the bond pad 244 c acting as a first conductor on theintrinsic region 232 can be electrically connected to one or moredevices on the MMIC for which ESD protection is desired. In the exampleof FIG. 6, a MIM capacitor 260 and an FET (field-effect transistor) 262are example devices that can be connected to the bond pad 244 c suchthat the bond pad 244 c facilitates electrical connectivity for suchdevices.

FIG. 6 further shows that the second conductor 246 c can be disposedrelative to the bond pad 244 c so as to be separated by at least someintrinsic semiconductor region 232 to thereby provide a pathway forESD-related charge to pass through the intrinsic region. In somesituations, such an ESD-related charge can pass from the bond pad 244 c,through the intrinsic region 232 (e.g., underneath an insulating surfacearea between the first and second conductors 244 c, 246 c) and to thesecond conductor 246 c, and then to the ground plane (not shown) throughthe interconnect metal 250 and the through-wafer via 252. As describedherein, such a selected direction can be made to be more likely byappropriately dimensioning and positioning the bond pad 244 c and/or thesecond conductor 246 c.

In the example shown in FIGS. 5 and 6, the first conductor 244 isdepicted as having a rectangular shape, and the second conductor 246 isdepicted as having an L-shape that shares its corner with one of therectangle's corners. It will be understood that other shapes, dimensionsand/or arrangements are also possible. Further, the first conductor doesnot need to be in the form of a bond pad, and can be part of otherstructures.

In some embodiments, a second conductor can have more or less segmentsthan the example L-shape. For example, a single-segment conductor havinga length greater than, equal to, or less than a side of a rectangularshaped bond pad can be positioned along that side so as to be separatedby a selected distance. In another example, a three-segment U-shapedconductor can be dimensioned and positioned so that the three segmentsare adjacent the corresponding three sides of a rectangular shaped bondpad. Other configurations are also possible.

In some embodiments, the first conductor and/or the second conductor canhave other shapes. For example, suppose that a first conductor has acircular shape. Then, a second conductor can be an arc having a radiusof curvature greater than the radius of the circular first conductor. Insome embodiments, such an arc can extend partially around thecircumference of the first conductor. Other shaped conductors can alsobe implemented.

In some embodiments, the first conductor and/or the second conductor canbe dimensioned and configured so as to facilitate and/or provide desiredESD protection and/or RF functionality. For example, a second conductorcan be shaped so as to facilitate or take advantage of different chargedistributions that can form on the first conductor. In some situations,charge can be distributed such that a corner portion of a firstconductor yields relatively high electrical field strength. A secondconductor can be dimensioned near such a corner so as to utilize orfacilitate such different electrical field strengths.

In another example, a second conductor can be dimensioned and shaped soas to yield little or substantially no impact on RF operation and/ornoise characteristics of one or more nearby devices. The L-shaped secondconductor strips are examples of such conductors that have little orsubstantially nil impact on RF properties. Examples of such benign-nessin RF properties and/or noise characteristics are described herein ingreater detail.

Referring to FIGS. 5 and 6, the interconnect metal 250 is depicted asextending into one end of a segment of the L-shaped conductor 246 c andextending from the other end of the segment so as to electricallyinterconnect the L-shaped conductors 246 to the via 252. In someembodiments, the interconnect metal 250 can be formed as strip segmentsso as to be electrically connected to the L-shaped conductors 246 butinsulated from the substrate (including the intrinsic region 232). Suchan interconnect metal 250 can be formed by, for example, patterned metaldeposition on top of an insulating layer. For example, and as describedin greater detail herein in reference to FIG. 7C, a metal layer 282 canbe formed on a substrate 232 so as to form an ohmic contact tofacilitate one or more features of ESD functionalities as describedherein. In the context of the example shown in FIGS. 5 and 6, the metallayer 282 can be formed so as to yield the example “L” shaped dischargestructure. The metal layer 282 can be covered with a dielectric layer(e.g., silicon nitride). The dielectric layer can be etched open (e.g.,by photolithographic method) so as to expose at least a portion of the“L” shaped metal layer 282. Then, an interconnect metal layer 284 can beformed so as to be in electrical contact with the ohmic metal 282. Inthe example configuration of FIGS. 5 and 6, the interconnect metal layer284 is depicted as interconnecting (250) the ohmic metal structures(246) to the via 252. Outside of the exposed opening for electricalcontact with the ohmic metal 282, the interconnect metal layer 284 canremain above the dielectric layer so as to be separated from thesemiconductor substrate. In the example shown in FIG. 7C, an additionalmetal layer 286 can be formed so as to provide a desired interconnectionconductivity property. In some implementations, either or both of themetal layers 284, 286 can be configured so as to provide a mechanicalstructure that reduces likelihood of delamination of one or moredielectric layers from the substrate. Examples of such a feature aredescribed herein in greater detail.

FIGS. 7A-7C show examples of how the first and second conductors similarto those of FIGS. 5 and 6 can be formed. FIG. 7A is a photograph of anESD structure 240 having a first conductor 244 and a second conductor246. A sectional cut was made to show sectional views of a layerassembly 270 of the first conductor 244 and a layer assembly 280 of thesecond conductor 246. In FIG. 7A, although the reference numeral 232 forthe intrinsic semiconductor region is indicated on the surface, such anintrinsic region may or may not extend to the outer surface. Forexample, there may be a protective layer that forms the outer surface.In some embodiments as described herein, an insulating surface layerbetween the first and second conductors 244, 246 is preferred, so thatan ESD charge pathway goes through the intrinsic semiconductor regionunderneath the surface.

FIG. 7B shows an enlarged sectional view of the layer assembly 270 ofthe first conductor 244 of FIG. 7A. FIG. 7C shows an enlarged sectionalview of the layer assembly 280 of the second conductor 246 of FIG. 7A.

FIG. 7B shows that in some implementations, the layer assembly 270 ofthe first conductor 244 can be formed so as to provide an ohmic contactbetween a bond pad surface of a metal layer 276 and the intrinsicsemiconductor region 232. Such an assembly can include an ohmic metallayer 272 formed on a surface of the intrinsic semiconductor region 232.Such an ohmic metal layer 272 can be formed from, for example, NiGeAu bya deposition technique such as sputter deposition, and can have athickness in a range of approximately 100 nm to 500 nm. The exampleohmic metal layer 272 shown in FIG. 7B has a thickness of about 300 nm.Other materials and/or other thicknesses can also be implemented.

The layer assembly 270 can further include a metal layer (274) formed soas to be in electrical contact with the ohmic metal 272. In someembodiments, an additional metal layer 276 can be formed over the metallayer 274 so as to yield a desired shaped first conductor (244 in FIG.7A) that is in electrical contact with the ohmic metal layer 272.

FIG. 7C shows that in some implementations, the layer assembly 280 ofthe second conductor 246 can be formed so as to provide an ohmic contactbetween a conductive strip (284 and/or 286) and the intrinsicsemiconductor region 232. Such an assembly can include an ohmic metallayer 282 formed on a surface of the intrinsic semiconductor region 232.Such an ohmic metal layer 282 can be formed from, for example, NiGeAu bya deposition technique such as sputter deposition, and can have athickness in a range of approximately 100 nm to 500 nm. The example seedlayer shown in FIG. 7C has a thickness of about 300 nm. Other materialsand/or other thicknesses can also be implemented.

As previously described in reference to FIGS. 5 and 6, the layerassembly 280 can further include an interconnect metal layer 284 formedso as to be in electrical contact with the ohmic metal 282. Theinterconnect metal layer can be formed by, for example, covering themetal layer 282 (e.g., with a dielectric layer such as silicon nitride)and etching a desired opening in the dielectric layer (e.g., byphotolithographic method) so as to expose at least a portion of theohmic metal layer 282. Then, the interconnect metal layer 284 can beformed so as to be in electrical contact with the ohmic metal 282. Inthe example configuration of FIGS. 5 and 6, the interconnect metal layer284 is depicted as interconnecting the “L” shaped ohmic metal structuresto the via 252. Outside of the exposed opening for electrical contactwith the ohmic metal 282, the interconnect metal layer 284 can remainabove the dielectric layer so as to be separated from the semiconductorsubstrate. In the example shown in FIG. 7C, an additional metal layer286 can be formed so as to provide a desired interconnectionconductivity property.

In some implementations, various layers associated with the first andsecond conductor structures can be formed together. Upon such formationof the layers, the first and second conductors can be separated by, forexample, patterned etching to yield desired shapes of the first andsecond conductors. In some implementations, the first and secondconductors can be formed substantially independently from each other. Insome implementations, the first and second conductors can be formed inany combination of the foregoing.

FIG. 8 shows a photograph of a photoemission image of a cross-section ofan ESD structure under bias. To obtain the image, the ESD structure wascross-sectioned, and probes were placed on ohmic-metal conductorstructures 244, 246 to provide the bias between the two conductors. Thesubstrate between the two conductors 244, 246 is a bulk intrinsic GaAssemiconductor (indicated as 232).

In the example photoemission image shown in FIG. 8, the brightestemissions are at the metal-semiconductor junctions, likely due tosurface states of the semiconductor that can be generated by thedisruption of the lattice during the metal-semiconductor alloy process.Dim emissions at various locations of the bulk intrinsic region are alsovisible; and these emissions are possibly due to recombinations ofelectrons with crystal defects.

As further shown in FIG. 8, a curved emission pattern 290 indicates flowof charge between the two conductors 244, 246 through the bulk intrinsicGaAs region 232. Such an emission pattern turned on when the potentialdifference between the two conductors 244, 246 exceeded about 36 volts.It will be understood that the turn-on voltage can be at other values orranges, depending on configuration of the two conductors and/or the bulkintrinsic region.

One or more features associated with various ESD structures describedherein can be implemented in integrated circuit devices and/or otherdevices, whether or not such devices are RF based devices. For example,a non-RF device having an intrinsic semiconductor region can be providedwith first and second conductors so as to form a charge pathway that canbe selectively turned on to provide ESD protection.

In some implementations, one or more features as described herein can beparticularly advantageous when utilized in RF-related devices. Examplesof how such one or more features can provide effective ESD protection ina manner that reduces or substantially eliminates RF-impact aredescribed in reference to FIGS. 9 and 10. FIG. 9A shows an example ofhow ESD structures positioned at different portions of an MMIC canprovide different effectiveness when subjected to a human body model(HBM) ESD test. FIG. 9B shows an example of how ESD structurespositioned at different portions of an MMIC can provide differenteffectiveness when subjected to a machine model (MM) ESD test.

In FIG. 9A, where example HBM ESD test results are shown, groups 300,302, 304 and 306 correspond to bond pads associated with Vdd (powersupply, 244 a in FIG. 5), RFout (RF output, 244 b), RFin (RF input, 244c) and Ven (enable, 244 d), respectively. Within each group, the fivebars represent the following example configurations: Left bar representsa prototype circuit without an ESD device; the second bar from leftrepresents a production circuit with an ESD as described herein (e.g., abenign discharge structure); the middle bar represents a productionversion of the prototype configuration (left bar); the second bar fromright represents a prototype circuit with separate ESD diodes at Vdd andVen locations; and the right bar represents a combination of the benigndischarge structure (BDS) and the ESD diodes. The machine model resultsshown in FIG. 9B have similar groups (310, 312, 314, 316) andarrangements of the five bars.

It is noted that in both HBM and MM cases, the configuration having anESD structure (second bar from the left) is significantly more effectiveat the RFin pin (groups 304, 314 in FIGS. 9A and 9B) than at other pins.For the RFout pin (groups 302, 312), the ESD structure (second bar) isshown to provide improved ESD voltage performance than those exampleswithout any ESD devices (left bar and middle bar). However, theimprovement is not as pronounced as in the RFin case. Such a differencein ESD voltage performance may be due to the RFin pad having connectedto it a large MIM capacitor, while the RFout pad has connected to it asmaller capacitor. Accordingly, in some implementations, an ESDstructure as described herein can be provided at or near RF ports wherecharge collecting capabilities already exist. As demonstrated in theforegoing example measurements, a larger charge collecting capability(e.g., large capacitor of RFin) can further enhance the performance ofthe ESD structure.

In some implementations, it can be desirable to have an ESD structurethat has a reduced or substantially nil impact on one or more operatingparameters (e.g., RF related parameters such as capacitance, inductance,etc.) For the purpose of description herein, such an impact on RFrelated parameter(s) is sometimes referred to as being benign. Asdescribed herein in greater detail, various embodiments of an ESDstructure having an intrinsic semiconductor interposed between twoconductors can provide such benign-ness for RF devices while providingan effective ESD protection functionality.

To demonstrate desirability of the foregoing combination of robust ESDprotection capability and benign-ness, consider the example results forVen shown in FIGS. 9A and 9B. In the example RF device associated withFIGS. 9A and 9B, the Ven pin (a DC input) has associated with it aseparate ESD protection diode that provides robust ESD protection forthe Ven pin. However, such a diode is not desirable at RF ports (inputand output) due to noise(s) and/or other undesirable RF effectsgenerated by or induced by the diode. Accordingly, the RFin pin in theexample is not equipped with such a separate ESD protection diode; andif not provided with an ESD protection structure (e.g., original andproduction lot cases), ESD voltage performance is relatively poor.However, with an ESD protection structure (second bar from the left)provided at the RFin pin, ESD voltage performance significantly exceedsthose of other configurations. The benign-ness of the ESD structure atthe RFin pin is described in greater detail in reference to FIGS. 10Aand 10B.

In some implementations as described herein, an ESD structure canprovide effective protection while having little or substantially nileffect on one or more RF-related performance parameters. FIGS. 10A and10B show examples of such performance parameters.

FIG. 10A shows an example of how an ESD structure as described hereincan provide protection while having little or substantially nil effecton a frequency-dependent S12 parameter of an example low-noise amplifier(LNA). In FIG. 10A, a baseline S12 profile 320 corresponds to aconfiguration where an RFin does not have an ESD structure. S12 profiles322, 324 and 326 correspond to configurations where ESDs are separatedfrom the pads by approximately 30 μm, 20 μm and 10 μm, respectively. Onecan see that the 20 μm case is very similar to the baseline case; andthe other two cases (10 μm and 30 μm cases) are also quite similar.

FIG. 10B shows another example of how an ESD structure can provideprotection while having little or substantially nil effect onfrequency-dependent noise of the example LNA. In FIG. 10B, a baselinegain profile 330 corresponds to a configuration where an RFin does nothave an ESD structure. Gain profiles 332, 334 and 336 correspond toconfigurations where ESDs are separated from the pads by approximately10 μm, 20 μm and 30 μm, respectively. One can see that the 10 μm and 20μm cases are very similar to the baseline case for most of the frequencyrange; and the 30 μm case is also quite similar.

FIG. 11 shows an example configuration of a benign discharge structure350 that can provide one or more advantageous features as describedherein. The structure 350 can be formed on a semiconductor substrate 366having an intrinsic region 360. First and second conductors 352, 356 canform ohmic contacts 354, 358 with the intrinsic region 360 so as toyield a discharge path 370 between the two conductors (352, 356) throughthe intrinsic region 360. As described herein, such conductors (352,356) can be dimensioned and separated so as to provide functionalitiessuch as benign-ness and likely direction of discharge. In FIG. 11, suchdimensions can be as follows: w1 represents a lateral width dimension ofthe first conductor 352, w2 represents a lateral width dimension of thesecond conductor 356, and w3 represents an edge-to-edge separation ofthe first and second conductors.

The benign discharge structure can further include an insulating region362 formed between the first and second conductors 352, 354. Such aninsulating region can be formed by, for example, doping (e.g., Boronimplantation) or other known methods. In some implementations, such aninsulating region can result in ESD-related charge to be built up in andtravel through the bulk of the intrinsic region 360 instead of at ornear the surface. In some embodiments, depth (d2) of the insulatingregion 362 can be selected to control how deep the discharge path 370should be. In FIG. 11, the insulating region 362 is depicted as having abox-like shape for illustration purpose; but it will be understood thatthe region 362 can have other shapes.

The benign discharge structure can further include one or moreinsulating regions about the intrinsic region 360, dimensioned tofurther define the discharge path 370. In the example depicted in FIG.11, such an insulating region is indicated as 364; and such a region canbe formed by appropriate doping (e.g., Boron implantation) or otherknown methods. In some embodiments, depth (d1) of the intrinsic region's360 lower boundary can also be selected to control charge build-upcapability (in the intrinsic region) and how deep the discharge path 370should be. Further, in the example shown in FIG. 11, the intrinsicregion 360 being bounded on the left side by the insulating region 364can inhibit discharge being routed to a region beneath RF components.

In the example shown in FIG. 11, the portion of the intrinsic region 360beneath the first conductor 352 (e.g., a bond pad) is significantlywider than the portion beneath the second conductor 356. Accordingly,the region beneath the first conductor has a larger volume, and thusgreater charge receiving capacity. Thus, when an ESD event occurs nearthe first conductor 352, the larger charge-receiving capacity of theintrinsic region below the first conductor 352 makes it likely that theESD-related charge will enter the first conductor 352 like a funnelinstead of another nearby location. Once in the funnel-like pathway, theappropriately shaped intrinsic region (turned on by the potentialdifference resulting from the ESD event) can guide the charge to thesecond conductor (and to a ground) and away from the RF components.

As described herein, a benign discharge structure can be formed near anexisting device having a charge holding capability so as to enhancecharge-receiving capability as well as increasing the likelihood thatESD-related charge will indeed be received there first. In the exampleconfiguration shown in FIG. 11, the first conductor 352 (e.g., a bondpad) is depicted as being electrically interconnected (372) to arelatively large capacitor 368. In some embodiments, one or more otherdevices can also be utilized.

In some embodiments, a benign discharge structure having one or more ofthe foregoing features can be implemented so as to not only providesubstantial benign-ness, but also to do so with very small areacommitment. In the example shown in FIGS. 5 and 6, the second conductors246 and their interconnects 250 are thin metal strips formed near bondpads and near the perimeter of the device 230. Accordingly, the originalarrangement and spacing of various components of the device 230 can besubstantially retained or be adjusted minimally.

FIG. 12 shows a process 400 that can be implemented to fabricate adischarge structure having one or more features described herein. Inblock 402, a semiconductor substrate can be provided. In someembodiments, such a substrate can include an intrinsic semiconductorportion. In block 404, a device can be formed or provided at a firstlocation of the substrate. In some embodiments, such a device caninclude one or more conductive portions that form ohmic contact(s) withan intrinsic semiconductor portion of the substrate. In block 406, aconductor can be formed or provided at a second location of thesubstrate so as to form a discharge path through the substrate betweenthe device and the conductor when their potential difference exceeds aselected value. In some embodiments, such a conductor can form ohmiccontact with the intrinsic semiconductor portion of the substrate, suchthat the discharge path is through the intrinsic portion.

In the context of the foregoing example where the device and theconductor form ohmic contacts with the intrinsic semiconductorsubstrate, FIG. 13 shows that a process 410 can be implemented tofabricate a discharge structure. In block 412, a semiconductor substratehaving an intrinsic region can be provided. In block 414, a first ohmiccontact can be formed at a first location of the intrinsic region. Inblock 416, a second ohmic contact can be formed at a second location ofthe intrinsic region so as to form a discharge path between the twoohmic contacts through the intrinsic region of the substrate. Such adischarge path can be configured to turn on when a potential differencebetween the two ohmic contacts exceeds a selected value.

For the purpose of description herein, an intrinsic semiconductor caninclude, but not limited to, GaAs substrate upon which epitaxial growthprocess(es) is/are performed. In some embodiments, an intrinsicsemiconductor can include, but not limited to, GaAs substrate which doesnot have significant concentration of dopants such as Boron.

One or more features of the present disclosure can be implemented in anumber of semiconductor materials. Such semiconductors can include, butare not limited to, gallium arsenide (GaAs), silicon, any othersemiconductors that can be implemented in a substantially intrinsicform. For example, in silicon-on-insulator (SOI) processes, there may besituations where at least a portion of a silicon substrate may not bedoped. Accordingly, a discharge structure having one or more features asdescribed herein can be implemented in such a configuration.

As described herein in reference to FIGS. 5-7, an interconnect conductorthat interconnects one or more ohmic metal contacts to ground can beconfigured to reduce the likelihood of a dielectric layer de-laminatingfrom an edge. De-lamination of layers such as a dielectric layertypically starts from an edge of the dielectric layer (e.g., at a streetthat defines an edge of the dielectric layer).

In some implementations, an interconnect conductor that interconnectsone or more ohmic metal contacts as described herein can be formed so asto form a perimeter around a given area. For the purpose of description,it will be understood that such a perimeter may or may not form acomplete enclosure of the area. For example, even if such a perimeter ofinterconnect conductor does not form a continuous enclosure, sufficientmechanical functionality for inhibiting edge-started de-lamination canbe provided.

FIG. 14 shows an example die 500 having a plurality of first ohmiccontact conductors 504 formed on an intrinsic semiconductor substrate asdescribed herein. Also shown are a plurality of second ohmic contactconductors 506 also formed on the intrinsic semiconductor substrate asdescribed herein so as to provide an ESD pathway between the first andsecond ohmic contacts through the intrinsic semiconductor. A dielectriclayer 502 is shown to be formed on the intrinsic semiconductorsubstrate, and one or more interconnect conductors 508, 510 are shown tobe formed so as to interconnect the second ohmic contacts 506 to aground through, for example, a through-wafer via 510. The one or moreinterconnect conductors 508, 510 can be electrically connected to thesecond ohmic contacts 506 through openings formed on the dielectriclayer 502. FIG. 15 shows example sectional views at such a location.Away from the second ohmic contacts 506, the one or more interconnectconductors 508, 510 can be separated from the intrinsic semiconductorsubstrate by the dielectric layer 502. FIG. 16 shows an examplesectional view at such a location.

FIG. 15A shows a sectional view of an interconnect conductor 508 formedover an ohmic metal 506 which is formed on an intrinsic semiconductorsubstrate 512. In some implementations, the ohmic metal 506 can beformed first on the substrate 512, followed by a dielectric layer 502that covers the substrate 512 and the ohmic metal 506. To form theinterconnect conductor 508 over the ohmic metal 506 so as to be inelectrical contact, an opening can be formed by, for example,photolithographic method.

As shown in FIG. 15A, the interconnect conductor 508 can be formed so asto include a portion 520 that extends over an edge 522 of the dielectriclayer 502. Such an overhang over the edge 522 can effectively pin downthe edge 522 mechanically so as to prevent or reduce the likelihood ofde-lamination of the dielectric layer 502, which often starts from anedge portion such as the example edge depicted as 522.

An extension of an interconnect conductor over an edge of a dielectriclayer can be configured in a number of different ways. For example, FIG.15B shows an example saw-tooth configuration where an interconnectconductor's (508) sectional shape includes an angled extension 530 thatwedges an edge portion 532 of a dielectric layer 502. Such aconfiguration where the edge 532 is wedged under the angled extension530 can also effectively pin down the edge 532 mechanically so as toprevent or reduce the likelihood of de-lamination of the dielectriclayer 502.

The interconnect conductor 508 is depicted as being formed over an ohmicmetal 506 which is in turn formed over an intrinsic semiconductorsubstrate 512. Formations of the ohmic metal 506, the dielectric layer502, and the opening in the dielectric layer 502 can be achieved inmanners similar to those described in reference to FIG. 15A.

As described herein in reference to FIG. 7C, a second interconnectconductor can be formed over a first interconnect conductor so as toachieve a desired conduction property. FIG. 15C shows an example where afirst interconnect conductor 508 is formed over an ohmic metal 506. Asecond interconnect conductor 510 is shown to be formed over the firstinterconnect conductor 508. The second interconnect conductor 510 caninclude an angled extension 540 that wedges an edge portion 542 of adielectric layer 502. Such a saw-tooth configuration where the edge 542is wedged under the angled extension 540 can also effectively pin downthe edge 542 mechanically so as to prevent or reduce the likelihood ofde-lamination of the dielectric layer 502. Formations of the ohmic metal506 on an intrinsic semiconductor substrate 512, the dielectric layer502, and the openings in the dielectric layer 502 for forming the firstand second interconnect conductors can be achieved in manners similar tothose described in reference to FIG. 15A.

As described herein, one or more layers of interconnect conductors canbe formed over a dielectric layer so as to be separated from anintrinsic semiconductor substrate. For such a portion of the one or moreinterconnect conductors, FIG. 16 shows an example where a firstinterconnect conductor 508 is formed over a dielectric layer 502 suchthat the first interconnect conductor 508 is separated from an intrinsicsemiconductor substrate 512. A second interconnect conductor 510 isshown to be formed over the first interconnect conductor 508. The secondinterconnect conductor 510 can include an angled extension 540 thatwedges an edge portion 542 of a dielectric layer 502. Such a saw-toothconfiguration where the edge 542 is wedged under the angled extension540 can also effectively pin down the edge 542 mechanically so as toprevent or reduce the likelihood of de-lamination of the dielectriclayer 502. Formations of the dielectric layer 502 over the substrate512, and formations of the first and second interconnect conductors 508,510 can be achieved in manners similar to those described in referenceto FIG. 15C.

FIG. 17 shows a process 550 that can be implemented to fabricate adevice that includes a de-lamination resistance feature as describedherein. Although described in the context of a benign dischargestructure, it will be understood that one or more features associatedwith such de-lamination resistance can be implemented without such anESD structure.

In block 552, a first ohmic metal contact can be formed on an intrinsicsemiconductor substrate. In block 554, a second ohmic metal contact canbe formed on the intrinsic semiconductor substrate and adjacent thefirst ohmic metal contact so as to yield a benign discharge structure.In block 556, a dielectric layer can be formed over the first and secondohmic metal contacts. In block 558, openings can be formed in thedielectric layer so as to expose at least portions of the first andsecond ohmic metal contacts. In block 560, an interconnect layer can beformed so as to be electrically connected to the second ohmic contact,and such that a portion of the interconnect layer mechanically pins anedge portion of the dielectric layer to thereby inhibit or reduce thelikelihood of de-lamination of the dielectric layer.

In some implementations, a dielectric layer described herein can beconfigured to function as a passivation layer. Thus, in someembodiments, a dielectric layer can be referred to as a passivationlayer.

In some implementations, devices and/or circuits having one or morefeatures described herein can be included in a semiconductor die, suchas an example die 600 schematically depicted in FIG. 18. The die 600 caninclude a semiconductor substrate 602 configured to receive a pluralityof components. As described herein, such a substrate can include atleast some intrinsic portions to facilitate ESD pathway(s) at, forexample, ESD structures 610 a, 610 b, 610 c, 610 d.

The die 600 can include an RF circuit 604, and such a circuit can beinterconnected to contact pads such as “RF in,” “RF out,” “Power,” and“Control.” At least some of such contact pads can be part of the ESDstructures 610. In some embodiments, the ESD structures 610 can beconfigured as described herein to provide ESD protection while havinglittle or no impact on RF functionality of the RF circuit 604 or the die600 itself. For such a configuration, at least the “RF in” and “RF out”contact pads can be provided with second ohmic contacts as describedherein to provide ESD protection. As described herein, the “RF in”portion can benefit significantly from the ESD structures as describedherein. Accordingly, in some embodiments, the die 600 can include an ESDstructure 610 at least for the “RF in” portion.

In some implementations, the RF circuit 604 can include a low-noiseamplifier (LNA) 606 configured to receive and amplify relatively weak RFsignals received by an antenna. Such an amplifier can be sensitive to RFparameters such as noise figure and s-parameter(s). As described herein,robust ESD protection can be provided for RF circuits such as an LNAcircuit while providing little or no impact on such RF parameters.

The foregoing LNA being part of the RF circuit 604 is intended to be anexample and not a requirement. In some implementations, the RF circuit604 may or may not include an LNA. In some implementations, the RFcircuit 604 can include any circuit that can benefit from ESD protectionthat has little or no impact on RF the circuit's RF operation. Such acircuit can include, for example, an LNA circuit, a power amplifiercircuit, a switching circuit, one or more control circuits, atransmitter circuit, and a receiver circuit.

In some implementations, a semiconductor die having one or more featuresdescribed herein can be included in a module. FIG. 19 shows an examplemodule having a die described in reference to FIG. 18.

In the example shown in FIG. 19, a module 700 can include a packagingsubstrate 702 configured to receive a plurality of components. In someembodiments, the packaging substrate 702 can include a laminatesubstrate. Such components can include a die 600 as described herein.

The die 600 can include an RF circuit 604 (e.g., an LNA circuit) and aplurality of contact pads. As described herein, at least some of suchcontact pads can be part of ESD structures configured to provide ESDprotection with little or no impact on RF operation of the RF circuit604. Such contact pads can facilitate formation of electricalconnections (e.g., wirebonds) 704 with corresponding contact pads 706 onthe packaging substrate 702. The contact pads 706 can be electricallyconnected to other contact pads disposed at other portions of the module700 to thereby facilitate electrical connections between the die 600 andcomponents external to the module 700.

In some embodiments, the module 700 can also include one or moresurface-mount devices (SMD) 710 mounted on the packaging substrate 702and configured to facilitate and/or complement the functionality of theRF circuit 604 to thereby yield a desired functionality of the module700.

In some embodiments, the module 700 can also include one or morepackaging structures to, for example, provide protection and facilitateeasier handling of the module 700. Such a packaging structure caninclude an overmold formed over the packaging substrate 702 anddimensioned to substantially encapsulate the various circuits andcomponents thereon.

It will be understood that although the module 700 is described in thecontext of wirebond-based electrical connections, one or more featuresof the present disclosure can also be implemented in other packagingconfigurations, including flip-chip configurations.

In some implementations, a device and/or a circuit having one or morefeatures described herein can be included in an RF device such as awireless device. Such a device and/or a circuit can be implementeddirectly in the wireless device, in a modular form as described herein,or in some combination thereof. In some embodiments, such a wirelessdevice can include, for example, a cellular phone, a smart-phone, ahand-held wireless device with or without phone functionality, awireless tablet, etc.

FIG. 20 schematically depicts an example wireless device 800 having oneor more advantageous features described herein. In the context of anLNA, one or more LNAs 606 as described herein are shown to receive RFsignals from an antenna 816 through a switch 814 and their respectiveduplexers 812. Such LNAs and related channels can facilitate, forexample, multi-band operation of the wireless device 800. In embodimentswhere the LNAs and the related ESD structures as described herein arepackaged into a module, such a module can include components in a dashedbox 600.

The LNAs 606 are shown to pass their amplified signals to a transceiver810 for further processing by a receiver circuit (not shown). Thetransceiver 810 can also generate RF signals for transmission and passsuch signals to power amplifiers (PAs) 811. Outputs of the PAs 811 areshown to be matched (via match circuits 820) and routed to the antenna816 via their respective duplexers 812 a-812 d and the band-selectionswitch 814. The band-selection switch 814 can include, for example, asingle-pole-multiple-throw (e.g., SP4T) switch to allow selection of anoperating band (e.g., Band 2). In some embodiments, each duplexer 812can allow transmit and receive operations to be performed simultaneouslyusing a common antenna (e.g., 816).

In embodiments where the PAs and the related ESD structures as describedherein are packaged into a module, such a module can include componentsin a dashed box 600. As described herein, other components of thewireless device 800 can include one or more ESD structures as describedherein; and such components can be implemented in one or more modules.Accordingly, other dashed box(es) 600 in addition to or in place of theexamples associated with the LNAs and the PAs can also be provided.

The transceiver 810 is also shown to interact with a baseband sub-system808 that is configured to provide conversion between data and/or voicesignals suitable for a user and RF signals suitable for the transceiver810. The transceiver 810 is also shown to be connected to a powermanagement component 806 that is configured to manage power for theoperation of the wireless device. Such power management can also controloperations of the baseband sub-system 808 and the module(s) 600.

The baseband sub-system 808 is shown to be connected to a user interface802 to facilitate various input and output of voice and/or data providedto and received from the user. The baseband sub-system 808 can also beconnected to a memory 804 that is configured to store data and/orinstructions to facilitate the operation of the wireless device, and/orto provide storage of information for the user.

A number of other wireless device configurations can utilize one or morefeatures described herein. For example, a wireless device does not needto be a multi-band device. In another example, a wireless device caninclude additional antennas such as diversity antenna, and additionalconnectivity features such as Wi-Fi, Bluetooth, and GPS.

Unless the context clearly requires otherwise, throughout thedescription and the claims, the words “comprise,” “comprising,” and thelike are to be construed in an inclusive sense, as opposed to anexclusive or exhaustive sense; that is to say, in the sense of“including, but not limited to.” The word “coupled”, as generally usedherein, refers to two or more elements that may be either directlyconnected, or connected by way of one or more intermediate elements.Additionally, the words “herein,” “above,” “below,” and words of similarimport, when used in this application, shall refer to this applicationas a whole and not to any particular portions of this application. Wherethe context permits, words in the above Detailed Description using thesingular or plural number may also include the plural or singular numberrespectively. The word “or” in reference to a list of two or more items,that word covers all of the following interpretations of the word: anyof the items in the list, all of the items in the list, and anycombination of the items in the list.

The above detailed description of embodiments of the invention is notintended to be exhaustive or to limit the invention to the precise formdisclosed above. While specific embodiments of, and examples for, theinvention are described above for illustrative purposes, variousequivalent modifications are possible within the scope of the invention,as those skilled in the relevant art will recognize. For example, whileprocesses or blocks are presented in a given order, alternativeembodiments may perform routines having steps, or employ systems havingblocks, in a different order, and some processes or blocks may bedeleted, moved, added, subdivided, combined, and/or modified. Each ofthese processes or blocks may be implemented in a variety of differentways. Also, while processes or blocks are at times shown as beingperformed in series, these processes or blocks may instead be performedin parallel, or may be performed at different times.

The teachings of the invention provided herein can be applied to othersystems, not necessarily the system described above. The elements andacts of the various embodiments described above can be combined toprovide further embodiments.

While certain embodiments of the inventions have been described, theseembodiments have been presented by way of example only, and are notintended to limit the scope of the disclosure. Indeed, the novel methodsand systems described herein may be embodied in a variety of otherforms; furthermore, various omissions, substitutions and changes in theform of the methods and systems described herein may be made withoutdeparting from the spirit of the disclosure. The accompanying claims andtheir equivalents are intended to cover such forms or modifications aswould fall within the scope and spirit of the disclosure.

What is claimed is:
 1. A device, comprising: a die having asemiconductor substrate with an intrinsic region; a metal layer in ohmiccontact with the intrinsic region; a passivation layer formed over themetal layer and the intrinsic region, the passivation layer defining anopening dimensioned to expose at least a portion of the metal layer; andan interconnect conductor disposed over the metal layer and electricallyconnected to the metal layer through the opening, the interconnectconductor including an extension that extends over an edge of theopening of the passivation layer to inhibit or reduce the likelihood ofthe passivation layer de-laminating from the edge.
 2. The device ofclaim 1 wherein the passivation layer includes a dielectric layer. 3.The device of claim 1 wherein the interconnect conductor is connected toa ground.
 4. The device of claim 1 further comprising a radio-frequency(RF) circuit implemented on the die.
 5. The device of claim 4 furthercomprising a contact pad connected to the RF circuit and in ohmiccontact with the intrinsic region, the contact pad and the metal layerconfigured so that a potential difference greater than a selected valuebetween the contact pad and the metal layer results in a conduction paththrough the intrinsic region between the contact pad and the metallayer.
 6. The device of claim 5 wherein the conduction path includes ametal-semiconductor-metal junction.
 7. The device of claim 6 wherein themetal-semiconductor-metal junction of the conduction path is configuredto provide a discharge path during an electrostatic discharge (ESD)event.
 8. The device of claim 5 wherein the contact pad is configured toreceive an input RF signal for the RF circuit.
 9. The device of claim 8wherein the RF circuit includes a low-noise amplifier (LNA).
 10. Thedevice of claim 1 wherein the interconnect conductor is configured as astrip that extends near a perimeter of the die.
 11. The device of claim1 wherein the semiconductor substrate includes gallium arsenide (GaAs).12. A method for fabricating a semiconductor device, the methodcomprising: providing a semiconductor substrate having an intrinsicregion; forming metal layer in ohmic contact with the intrinsic region;forming a passivation layer over the metal layer and the intrinsicregion such that the passivation layer defines an opening dimensioned toexpose at least a portion of the metal layer; and forming aninterconnect conductor over the metal layer such that the interconnectconductor is electrically connected to the metal layer, the interconnectconductor including an extension that extends over an edge of theopening of the passivation layer to inhibit or reduce the likelihood ofthe passivation layer de-laminating from the edge.
 13. The method ofclaim 12 further comprising forming a radio-frequency circuit on thesemiconductor substrate.
 14. The method of claim 13 further comprisingforming and connecting a contact pad to the RF circuit, the contact padin ohmic contact with the intrinsic region, the contact pad and themetal layer configured so that a potential difference greater than aselected value between the contact pad and the metal layer results in aconduction path through the intrinsic region between the contact pad andthe metal layer.
 15. The method of claim 12 wherein the passivationlayer includes a dielectric layer.
 16. A radio-frequency (RF) modulecomprising: a packaging substrate configured to receive a plurality ofcomponents; and a semiconductor die mounted on the packaging substrate,the die including an intrinsic region, the die further including a metallayer in ohmic contact with the intrinsic region, the die furtherincluding a passivation layer formed over the metal layer and theintrinsic region, the passivation layer defining an opening dimensionedto expose at least a portion of the metal layer, the die furtherincluding an interconnect conductor disposed over the metal layer andelectrically connected to the metal layer through the opening, theinterconnect conductor including an extension that extends over an edgeof the opening of the passivation layer to inhibit or reduce thelikelihood of the passivation layer de-laminating from the edge.
 17. Themodule of claim 16 further comprising a ground plane electricallyconnected to the interconnect conductor.
 18. The module of claim 17further comprising a radio-frequency (RF) circuit implemented on thedie.
 19. The module of claim 18 further comprising a contact padconnected to the RF circuit and in ohmic contact with the intrinsicregion, the contact pad and the metal layer configured so that apotential difference greater than a selected value between the contactpad and the metal layer results in a conduction path through theintrinsic region between the contact pad and the metal layer.